JP2005241481A - Temperature sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a temperature sensor excellent in waterproofness even in the cases the metallic cylindrical member is caulked with an elastic seal member while interleaving a braided tube. <P>SOLUTION: The temperature sensor 100 is formed with caulking the braided tube 20 together with the elastic seal member 13 on the joint 6. The 1st caulking part 61 is provided on the point where the overlapping part 71 of elastic seal member 13 and the glass braided tube is formed, and the 2nd caulking part 62 is formed in the elastic seal member 13 nearer to the tip part than the overlapping part 71. By forming the 2nd caulking part 62 the outer surface of the elastic seal member 13 is brought into a close contact with the inner surface of the joint 6, therefore, if a minute gap between the joint 6 and the glass braided tube 20 at the 1st caulking part 61 where the glass braided tube 20 is inter leaved, at the 2nd caulking part 62 hermetic seal between the elastic seal member 13 and the joint 6 is secured, accordingly the waterproofness of the temperature sensor is secured. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a temperature sensor, and a temperature sensing element is disposed in a flow passage through which a fluid to be measured (for example, exhaust gas) flows, such as in a catalytic converter or an exhaust pipe of an exhaust gas purifying apparatus for an automobile. The present invention relates to a temperature sensor that detects the temperature of the sensor.

  2. Description of the Related Art Conventionally, a temperature sensor that detects the temperature of exhaust gas flowing through an exhaust gas flow path such as the inside of a catalytic converter or an exhaust pipe of an automobile exhaust gas purification device by a temperature sensing element (for example, a thermistor element), a so-called exhaust temperature sensor has been known. It has been. A general structure of this temperature sensor includes a sheath member in which a pair of conductive core wires are insulated and held in a metal outer cylinder, a thermistor element connected to the core wire on the distal end side of the sheath member, and a sheath It consists of a pair of lead wires for external circuit connection connected to the core wire on the rear end side of the member. And a sheath member is arrange | positioned inside a metal cylindrical member, and a lead wire is pulled outside through the lead wire penetration hole of the elastic seal member inserted in the rear-end part inner side of this metal cylindrical member.

Here, since it is necessary to protect the lead wire drawn out of the metal cylindrical member from an external force such as a flying stone, it is generally arranged in a braided tube having excellent heat resistance such as a glass braided tube. is there. As a temperature sensor provided with such a braided tube, the tip side of the braided tube is arranged so as to generate an overlapping portion with respect to the radially outer side of the elastic seal member, and a portion corresponding to the overlapping portion of the metal cylindrical member is arranged. There is known one in which a braided tube is fixed to a metal cylindrical member together with an elastic seal member by caulking inward (see, for example, Patent Document 1).
JP 2002-221451 (FIGS. 1 and 4)

  However, like the temperature sensor of Patent Document 1, when the metal cylindrical member is caulked from the outside inward with the braided tube interposed, and the elastic seal member is caulked and fixed to the metal cylindrical member, Since the braided tube itself has a characteristic that it is difficult to be elastically deformed, a minute gap tends to occur between the inner peripheral surface of the metal cylindrical member and the outer peripheral surface of the braided tube. Therefore, the airtightness between the elastic seal member and the metal cylindrical member is lowered, and the waterproof property tends to be lowered. In addition, since the braided tube is formed by subjecting a sleeve made of glass fiber, polyester fiber or the like to a cylindrical shape and surface treatment with a varnish (for example, silicone varnish), water vapor is inside the tube itself (braided). May be transmitted. Therefore, in order to further improve the waterproofness of the temperature sensor, it is necessary to take measures to prevent water vapor that has passed through the inside of the braided tube itself from entering the inside of the metal cylindrical member. In particular, the actual usage environment of temperature sensors in recent years may be severe in the wet water environment conditions, and it is important to take measures against the deterioration of waterproofness due to the above-mentioned problems.

  The present invention has been made in view of the present situation, and even when the elastic seal member is caulked and fixed to the metal cylindrical member with the braided tube interposed, the elastic seal member, the metal cylindrical member, It is an object to provide a temperature sensor excellent in waterproofness that can sufficiently prevent the water vapor passing through the inside of the braided tube itself from entering the inside of the metal cylindrical member. To do.

  The solution includes a sheath member formed by insulatingly holding a conductive core wire inside the outer tube, a metal cylindrical member surrounding the periphery of the sheath member in the radial direction, and connected to the core wire on the distal end side of the sheath member. A temperature sensing element, a lead wire connected to the core wire on the rear end side of the sheath member, and a lead wire insertion hole for drawing the lead wire from the inside of the metal cylindrical member to the outside. A temperature sensor comprising: an elastic seal member inserted inside the metal tube member; and a braided tube surrounding the lead wire drawn out of the metal cylindrical member, wherein the braided tube and the elastic seal member are a braided tube. The tip end of the metal seal member is disposed so as to be located radially outside the rear end of the elastic seal member, and the elastic seal member is disposed at a position spaced apart in the axial direction of the metal cylindrical member. The cylindrical member The first caulking part is fixed to the metal cylindrical member by the first caulking part and the second caulking part formed by caulking in the direction, and the first caulking part is located at a position where an overlapping part is generated in the elastic seal member. On the other hand, the second caulking portion is a temperature sensor formed at a position closer to the tip than the overlapping portion in the elastic seal member.

  The temperature sensor of the present invention has a structure in which a braided tube is caulked and fixed to a metal cylindrical member together with an elastic seal member, but the braided tube is positioned ( It does not caulk only the intervening part. That is, in the temperature sensor of the present invention, the first caulking part and the second caulking part for caulking and fixing the elastic seal member to the metal cylindrical member are provided at positions separated from each other in the axial direction of the metal cylindrical member. More specifically, in the elastic seal member, the first caulking portion is positioned at a position where the overlapping portion with the braided tube is formed, and the elastic sealing member is positioned at the tip side of the overlapping portion. A second caulking portion is provided.

  By forming a second caulking portion in a shape that does not interpose a braided tube with the elastic seal member on the tip side of the first caulking portion of the metal cylindrical member, the outer peripheral surface of the elastic seal member is made of metal. The inner circumferential surface of the cylindrical member can be tightly fixed. As a result, even if a minute gap is generated between the inner peripheral surface of the metal tubular member and the outer peripheral surface of the braided tube in the first caulking portion where the braided tube is interposed between the elastic seal member and the outer peripheral surface of the braided tube. Since the airtightness between the elastic seal member and the metal cylindrical member is ensured at the two caulking portions, it is possible to prevent a decrease in the airtightness of the temperature sensor. Even if water vapor permeates through the inside of the braided tube itself, the second caulking portion is provided on the tip side of the braided tube so that the water vapor can penetrate inside the metal cylindrical member. Can be blocked.

  Therefore, according to the temperature sensor of the present invention, the braided tube can be fixed to the metal cylindrical member together with the elastic seal member, and water can be prevented from entering the inside of the metal cylindrical member. Can be provided.

  The temperature sensing element may be any element as long as its electrical characteristics change with temperature change, and includes a thermistor sintered body made of a metal oxide semiconductor or a metal resistor such as Pt as a temperature sensing part. A thing can be used suitably. The elastic seal member may be any member having elasticity, and silicon rubber, fluorine rubber, or the like can be suitably used.

  A temperature sensor 100 according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a partially broken sectional view showing the structure of a temperature sensor 100 of the present invention. This temperature sensor 100 uses the thermistor element 2 as a temperature-sensitive element, and exhausts the thermistor element 2 housed inside the metal tube 3 by mounting the sensor 100 on a mounting portion of an exhaust pipe of an automobile. It is arranged in an exhaust pipe through which gas flows to be used for temperature detection of exhaust gas.

  The metal tube 3 made of SUS310S extending in the axial direction has a cylindrical shape with the distal end side 31 closed, and the thermistor element 2 is accommodated inside the distal end side 31. The cement 10 is filled inside the metal tube 3 and around the thermistor element 2. The rear end side 32 of the metal tube 3 is open, and the rear end side 32 is inserted inside the flange 4 made of SUS310S. In addition, the cement 10 used for this Embodiment consists of the aggregate which has an alumina powder as a main component, and the glass component containing Si.

  The flange 4 includes a sheath portion 42 that extends in the axial direction, and a protrusion 41 that is located on the distal end side of the sheath portion 42 and has an outer diameter larger than that of the sheath portion 42. The protrusion 41 has a seat surface 45 having a shape corresponding to a taper portion of an exhaust pipe attachment portion (not shown) on the tip side, and the seat surface 45 is in close contact with the taper portion of the attachment portion, thereby Gas is prevented from leaking outside the exhaust pipe. The sheath portion 42 is formed in a ring shape, and has a two-stage shape including a front end side step portion 44 located on the front end side and a rear end side step portion 43 having an outer diameter smaller than that of the front end side step portion 44. ing.

  The metal tube 3 is press-fitted inside the flange 4, and the overlapping portion between the outer peripheral surface of the metal tube 3 and the inner peripheral surface of the rear end side step portion 43 of the sheath portion 42 is laser welded in the circumferential direction. By performing this laser welding, as shown in FIG. 1, a welded portion L <b> 1 straddling the rear end side stepped portion 43 of the sheath portion 42 and the metal tube 3 is formed, and the metal tube 3 is strong against the flange 4. Will be fixed to

  A nut 5 having a hexagonal nut portion 51 and a screw portion 52 is rotatably fitted around the flange 4. The temperature sensor 1 is fixed by bringing the seating surface 45 of the protruding portion 41 of the flange 4 into contact with the mounting portion of the exhaust pipe and screwing the nut 5 into the mounting portion. A cylindrical joint 6 made of SUS304 is joined to the radially outer side of the distal end side step portion 44 in the sheath portion 42 of the flange 4 in an airtight state. Specifically, the distal end side of the joint 6 is press-fitted into the distal end side step portion 44 of the sheath portion 42 so that the outer peripheral surface of the distal end side step portion 44 of the sheath portion 42 overlaps with the outer peripheral surface of the joint portion 6. The tip side stepped portion 44 is laser welded in the circumferential direction. By performing this laser welding, as shown in FIG. 1, a welded portion L <b> 2 straddling the distal end side stepped portion 44 of the sheath portion 42 and the joint 6 is formed.

  A sheath member 8 that includes a pair of core wires 7 is disposed inside the metal tube 3, the flange 4, and the joint 6. Although not shown in detail, the sheath member 8 is filled in a metal outer tube made of SUS310S, a pair of conductive core wires 7 made of SUS310S, and insulates between the outer tube and each core wire 7. However, it is composed of insulating powder for holding the core wire 7. A pair of electrode wires 9 made of a Pt—Rh alloy constituting the thermistor element 2 is connected to the core wire 7 protruding from the distal end side of the sheath member 8 (specifically, the outer cylinder of the sheath member 8) inside the metal tube 3. Is done. The electrode wire 9 is provided in such a manner that the tip end side is embedded in the thermistor sintered body that forms the temperature sensing part of the thermistor element 2. The electrode wire 9 and the core wire 7 are connected to each other by spot-like laser welding.

  The core wire 7 protruding to the rear end side of the sheath member 8 disposed inside the joint 6 is connected to the pair of lead wires 12 via the crimping terminals 11. The pair of core wires 7 and the pair of crimp terminals 11 are insulated from each other by an insulating tube 15.

  Here, the configuration of the lead wire 12 is shown in FIG. FIG. 3 shows a radial cross section of one lead wire 12, a second electric wire 17 made of seven stainless wires in the central portion, and twelve nickel-plated annealed copper surrounding the second electric wire 17. The first electric wire 18 made of wire is covered with an insulating covering member 19 made of tetrafluoroethylene resin. Each first electric wire 18 and each second electric wire 19 are twisted mixed stranded wires.

  The pair of lead wires 12 is led out from the inside of the joint 6 to the outside through the lead wire insertion hole 85 of the elastic seal member 13 made of silicon rubber inserted inside the rear end portion of the joint 6. It is connected to the terminal member of the connector 21 for connecting to an external circuit (for example, ECU). As a result, the output of the thermistor element 2 is taken out from the core wire 7 of the sheath member 8 to the external circuit (not shown) via the lead wire 12 and the connector 21, and the temperature of the exhaust gas is detected. Further, the lead wire 12 is covered with a glass braided tube 20 for protecting it from external forces such as stepping stones. As will be described later, the glass braided tube 20 is jointed with the elastic seal member 13 at its tip. 6 is fixed by caulking. In the present embodiment, the glass braided tube 20 is formed by applying and drying a silicone varnish on a sleeve in which glass fibers are braided into a cylindrical shape.

  Next, the main part of the present invention will be described with reference to an enlarged sectional view showing a fixing structure in which the elastic seal member 13 is caulked and fixed inside the joint 6. The elastic seal member 13 inserted inside the rear end portion of the joint 6 is elastically deformed by forming a first crimping portion 61 and a second crimping portion 62 at positions separated from each other in the axial direction of the joint 6. It is fixed (clamped and fixed) to the joint 6 in a state of being compressed and deformed.

  Here, in a state before the joint 6 is crimped, the elastic seal member 13 has a large-diameter portion 81 located on the distal end side and a small-diameter portion having an outer diameter smaller than that of the large-diameter portion 81 as shown in FIG. 83 is formed in a two-stage shape. And the front-end | tip part of the glass braided tube 20 is arrange | positioned so that the overlapping part 71 may be produced in the form located in the radial direction outer side of the small diameter part 83 of this elastic seal member 13, and the 1st crimp part 61 is an elastic seal member. 13 is formed by caulking the joint 6 inward so as to correspond to the position where the overlapping portion 71 is generated. That is, in the first caulking portion 61, the glass braided tube 20 is caulked together with the elastic seal member 13. The first caulking portion 61 is formed by performing hexagonal caulking from the outside of the joint 6 toward the inside. As described above, in the present embodiment, by providing the first caulking portion 61, the glass braided tube 20 has the inner peripheral surface of the joint 6 (first caulking portion 61) and the small diameter portion 83 of the elastic seal member 13. It is fixed to the joint 6 so as to be sandwiched between the outer peripheral surface.

  On the other hand, the second caulking portion 62 is formed at a position on the distal end side of the overlapping portion 71 in the elastic seal member 13, that is, around the outer peripheral surface of the large diameter portion 81. In addition, the 2nd crimping part 62 is formed by performing Happo-maru crimping from the outer side of the coupling 6 toward the inner side. Since the glass braided tube 20 is not disposed around the large-diameter portion 81 of the elastic seal member 13, the large-diameter portion 81 of the elastic seal member 13 is connected to the joint 6 (second It is fixed tightly to the crimping part 62). Thereby, the airtightness between the elastic seal member 13 and the joint 6 is ensured.

The temperature sensor 100 is manufactured as follows.
First, deep drawing is performed on a steel plate made of SUS310S to form a cylindrical metal tube 3 whose front end is closed. Also, a sheath portion having an inner hole for press-fitting and fixing the metal tube 3 by separately performing cold forging and cutting on the metal body of SUS310S, and a front end side step portion 44 and a rear end side step portion 43 The flange 4 having 42 and a projecting portion 41 having an outer diameter larger than the sheath portion 42 is formed.

  Next, the electrode wire 9 of the thermistor element 2 manufactured separately and the core wire 7 of the sheath member 8 are overlapped so as to overlap each other by a predetermined dimension, and are laser-welded to each other so that the thermistor element 2 is connected to the sheath member 8. A temperature sensitive element assembly is produced. Then, the metal tube 3 is press-fitted and fixed in the inner hole of the flange 4, and a portion where the outer peripheral surface of the metal tube 3 overlaps with the inner peripheral surface of the rear end side step portion 43 of the sheath portion 42 is laser welded in the circumferential direction.

  Thereafter, the metal tube 3 is filled with an insulating paste to be the cement 10, the temperature sensing element assembly is inserted into the metal tube 3 to a predetermined position, and heat treatment is performed to solidify the insulating paste. .

  Next, the rear end side of the lead wire 12 is connected to the terminal member of the connector 21, and the glass braided tube 20 having a predetermined dimension prepared in advance is covered with the front end side of the lead wire 12 so as to cover the periphery of the pair of lead wires 12. Wear from. Further, the elastic seal member 13 is attached so that the lead wire 12 is inserted into the lead wire insertion hole 85. Then, the insulating tube 15 is inserted into each lead wire 12, and the joint 6 made of SUS304 is inserted from the tip end side of the lead wire 12 so that the lead wire 12 is finally arranged inside, and an upper sensor intermediate is prepared. . As shown in FIG. 4, the elastic seal member 13 is preliminarily formed into a two-stage shape including a large diameter portion 81 located on the distal end side and a small diameter portion 83 having an outer diameter smaller than the large diameter portion 81. The formed one was used.

  Then, the lead wire 12 of the sensor upper intermediate body and the rear end portion of the core wire 7 of the sheath member 8 are connected via the crimping terminal 11, and the insulating tube 15 is moved to a position covering the periphery of each crimping terminal 11. . Thereafter, the joint 6 is press-fitted into the front end side step portion 44 of the sheath portion 42 of the flange 4, and the joint 6 and the front end side step portion 44 are laser welded in the circumferential direction.

  Next, the elastic sealing member 13 is inserted into the rear end side inside of the joint 6, and the glass braided tube 20 is formed so that the front end portion of the glass braided tube 20 overlaps with the small diameter portion 83 of the elastic sealing member 13. Is moved toward the inside of the joint 6. At this time, the glass braided tube 20 is moved until the tip of itself touches the rear end face 84 (see FIG. 3) of the large diameter portion 81 of the elastic seal member 13. Thereby, positioning of the glass braided tube 20 with respect to the axial direction of the elastic seal member 13 is ensured, and an overlapping portion 71 having a predetermined overlapping dimension can be generated.

  Then, hexagonal caulking is performed from the outside of the joint 6 inward to form the first caulking portion 61 at a position in the elastic seal member 13 where the overlapping portion 71 is generated. The second caulking portion 62 is formed at a position on the tip side of the overlapping portion 71 in the elastic seal member 13 by performing inward round caulking from the inner side to the inner side. Then, the nut 5 is assembled and the manufacture of the temperature sensor 100 is completed. In addition, about the 1st crimping part 61 and the 2nd crimping part 62, although manufacturing efficiency can be improved by performing simultaneously crimping, either one crimping part is formed in advance. After that, it goes without saying that the other caulking portion may be formed.

  As described above, the temperature sensor 100 according to the present embodiment has a structure in which the glass braided tube 20 is caulked and fixed to the joint 6 together with the elastic seal member 13. A first crimping portion 61 is formed at a position where an overlapping portion 71 with the braided tube 20 is generated, and a second crimping portion 62 is formed at a position on the distal end side of the overlapping portion 71 in the elastic seal member 13. .

  As described above, the second caulking portion 62 having a shape in which the glass braided tube 20 is not interposed between the elastic sealing member 13 and the elastic sealing member 13 is formed on the distal end side of the first caulking portion 61 in the joint 6. The outer peripheral surface of the seal member 13 can be tightly fixed to the inner peripheral surface of the joint 6. Thereby, even if a minute gap is generated between the inner peripheral surface of the joint 6 and the outer peripheral surface of the glass braided tube 20 in the first crimped portion 61 in which the glass braided tube 20 is interposed, the second caulked portion. In 62, the airtightness between the elastic seal member 13 and the joint 6 is ensured, and it is possible to prevent the airtightness of the temperature sensor 100 and hence the waterproofness from being lowered. Further, by providing the second caulking portion 62, it is possible to block the intrusion of the water vapor into the joint 6 even if the water vapor passes through the inside of the glass braided tube 20 itself.

  In the present embodiment, the glass braided tube 20 corresponds to a braided tube in the claims, and the joint 6 corresponds to a metal cylindrical member.

  In the above, the present invention has been described with reference to the embodiment. However, the present invention is not limited to the above embodiment, and it is needless to say that the present invention can be appropriately modified and applied without departing from the gist thereof. Absent. For example, in the above embodiment, the metal tube 3 with the sheath member 8 disposed on the inside is fixed to the flange 4, but the thermistor element disposed on the distal end side of the sheath member is covered (enclosed) so as to be present. A bottom cylindrical metal cap may be joined to the outer periphery of the outer end of the sheath member, and the sheath member may be directly fixed to the flange.

  Moreover, in the said embodiment, although the 1st crimping part 61 was formed by hexagonal crimping and the 2nd crimping part 62 was formed by Happo-maru crimping, a crimping method is not limited to this but changes suitably. May be. Furthermore, in the said embodiment, although the 1st crimp part 61 and the 2nd crimp part 62 are formed as an essential requirement, you may increase the number of crimp parts as needed. The temperature sensor 100 can be applied not only to the exhaust temperature sensor but also to a temperature sensor attached to a flow path through which a liquid such as water or oil flows as a fluid to be measured.

It is a fragmentary sectional view which shows the whole structure of the temperature sensor of embodiment. It is an expanded sectional view which shows the elastic seal member vicinity which is a principal part among the temperature sensors shown in FIG. It is radial direction sectional drawing of the lead wire in the temperature sensor shown in FIG. In the temperature sensor shown in FIG. 1, it is explanatory drawing of the elastic seal member in the state before forming a 1st crimping part and a 2nd crimping part (before elastic deformation).

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Temperature sensor, 2 ... Thermistor element (temperature sensing element), 3 ... Metal tube, 4 ... Flange, 5 ... Nut, 6 ... Joint (metal cylindrical member), 7 ... core wire, 8 ... sheath member, 12 ... lead wire, 13 ... elastic seal member, 20 ... glass braided tube (braided tube), 61 ... first caulking part, 62 ... second caulking part, 71 ... overlapping part, 81 ... large diameter part, 83 ... small diameter part, 85 ... lead wire insertion hole

Claims (1)

A sheath member formed by insulatingly holding a conductive core wire inside the outer cylinder;
A metal cylindrical member surrounding the sheath member in the radial direction;
A temperature sensitive element connected to the core wire at the distal end side of the sheath member;
A lead wire connected to the core wire on the rear end side of the sheath member;
An elastic seal member having a lead wire insertion hole for pulling out the lead wire from the inside of the metal cylindrical member to the outside, and being inserted into the metal cylindrical member;
A braided tube surrounding the periphery of the lead wire drawn out of the metal cylindrical member, and a temperature sensor comprising:
The braided tube and the elastic seal member are arranged so that an end portion of the braided tube is located on the radially outer side of the rear end portion of the elastic seal member so as to form an overlapping portion.
The elastic seal member is formed by a first caulking portion and a second caulking portion that are formed by caulking the metal cylindrical member inward at a position spaced apart in the axial direction of the metal cylindrical member. The first caulking portion is fixed to a metal cylindrical member, and the first caulking portion is formed at a position where the overlapping portion is generated in the elastic seal member, while the second caulking portion is formed of the elastic seal member. A temperature sensor characterized in that the temperature sensor is formed at a position closer to the tip than the overlapping portion.